Mechanics and dynamics of thread milling process

Min Wan; Yusuf Altintas

doi:10.1016/j.ijmachtools.2014.07.006

Mechanics and dynamics of thread milling process

Min Wan, Yusuf Altintas

School of Mechanical Engineering

University of British Columbia

Research output: Contribution to journal › Article › peer-review

77 Scopus citations

Abstract

This paper presents the mechanics and dynamics of thread milling operations. The tool follows a helical path around the wall of the pre-machined hole in thread milling, which has varying tool-part engagement and cut area during one threading cycle. The variation of cut area that reflects the kinematics of threading as well as structural vibrations is modeled along the helical, threading path. The mechanics of the process are first experimentally proven, followed by the formulation of dynamic thread milling which is periodic in threading cycle, in a semi-discrete time domain. The stability of the operation is predicted as a function of spindle speed, axial depth of cut, cutter path and tool geometry. The mechanics and stability models are experimentally proven in opening M16×2 threads with a five-fluted helical tool on a Steel AISI1045 workpiece.

Original language	English
Pages (from-to)	16-26
Number of pages	11
Journal	International Journal of Machine Tools and Manufacture
Volume	87
DOIs	https://doi.org/10.1016/j.ijmachtools.2014.07.006
State	Published - Dec 2014

Keywords

Chatter
Semi-discretization method
Thread milling

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10.1016/j.ijmachtools.2014.07.006

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title = "Mechanics and dynamics of thread milling process",

abstract = "This paper presents the mechanics and dynamics of thread milling operations. The tool follows a helical path around the wall of the pre-machined hole in thread milling, which has varying tool-part engagement and cut area during one threading cycle. The variation of cut area that reflects the kinematics of threading as well as structural vibrations is modeled along the helical, threading path. The mechanics of the process are first experimentally proven, followed by the formulation of dynamic thread milling which is periodic in threading cycle, in a semi-discrete time domain. The stability of the operation is predicted as a function of spindle speed, axial depth of cut, cutter path and tool geometry. The mechanics and stability models are experimentally proven in opening M16×2 threads with a five-fluted helical tool on a Steel AISI1045 workpiece.",

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AB - This paper presents the mechanics and dynamics of thread milling operations. The tool follows a helical path around the wall of the pre-machined hole in thread milling, which has varying tool-part engagement and cut area during one threading cycle. The variation of cut area that reflects the kinematics of threading as well as structural vibrations is modeled along the helical, threading path. The mechanics of the process are first experimentally proven, followed by the formulation of dynamic thread milling which is periodic in threading cycle, in a semi-discrete time domain. The stability of the operation is predicted as a function of spindle speed, axial depth of cut, cutter path and tool geometry. The mechanics and stability models are experimentally proven in opening M16×2 threads with a five-fluted helical tool on a Steel AISI1045 workpiece.

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KW - Semi-discretization method

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JO - International Journal of Machine Tools and Manufacture

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Mechanics and dynamics of thread milling process

Abstract

Keywords

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